The disclosure relates to a sequential infiltration synthesis apparatus comprising: a reaction chamber constructed and arranged to accommodate at least one substrate; a first precursor flow path to provide the first precursor to the reaction chamber when a first flow controller is activated; a second precursor flow path to provide a second precursor to the reaction chamber when a second flow controller is activated; a removal flow path to allow removal of gas from the reaction chamber; a removal flow controller to create a gas flow in the reaction chamber to the removal flow path when the removal flow controller is activated; and, a sequence controller operably connected to the first, second and removal flow controllers and the sequence controller being programmed to enable infiltration of an infiltrateable material provided on the substrate in the reaction chamber. The apparatus may be provided with a heating system.

A film formation method includes (A) to (C) below. (A) Providing a substrate including, on a surface of the substrate, a first region in which a first material is exposed and a second region in which a second material different from the first material is exposed. (B) Supplying, to the surface of the substrate, vapor of a solution that contains a raw material of a self-assembled monolayer and a solvent by which the raw material is dissolved, and selectively forming a self-assembled monolayer in the first region. (C) Forming a desired target film in the second region by using the self-assembled monolayer formed in the first region.

The present invention provides a polybenzoxazole precursor, which comprises a structure of formula (I):

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wherein the definitions of Y, Z, R.sub.1, i, j, and V are provided herein. By means of the polybenzoxazole precursor, the resin composition of the present invention is able to form a film with high frequency characteristics and high contrast.

A semiconductor device includes a substrate, a pair of semiconductor fins, a dummy fin structure, a gate structure, a plurality of source/drain structures, a crystalline hard mask layer, and an amorphous hard mask layer. The pair of semiconductor fins extend upwardly from the substrate. The dummy fin structure extends upwardly above the substrate and is laterally between the pair of semiconductor fins. The gate structure extends across the pair of semiconductor fins and the dummy fin structure. The source/drain structures are above the pair of semiconductor fins and on either side of the gate structure. The crystalline hard mask layer extends upwardly from the dummy fin and has an U-shaped cross section. The amorphous hard mask layer is in the first hard mask layer, wherein the amorphous hard mask layer having an U-shaped cross section conformal to the U-shaped cross section of the crystalline hard mask layer.

A film formation method includes: preparing a substrate including, on its surface, a first region in which a first material is exposed and a second region in which a second material different from the first material is exposed; selectively forming a self-assembled monolayer in the first region, among the first region and the second region; and forming a desired target film in the second region, among the first region and the second region, by using the self-assembled monolayer formed in the first region, wherein the selectively forming the self-assembled monolayer includes: selectively forming the self-assembled monolayer in the first region by using a first processing liquid including a first raw material of the self-assembled monolayer; and modifying the self-assembled monolayer, by using a second processing liquid including a second raw material of the self-assembled monolayer at a concentration different from a concentration of the first processing liquid.

A method of manufacturing a semiconductor device, includes forming a sacrificial film made of a polymer having a urea bond on a substrate by supplying an amine and an isocyanate to a surface of the substrate, wherein the sacrificial film is provided in a specific region of the substrate; performing a predetermined process on the substrate on which the sacrificial film is formed; and removing the sacrificial film by heating the substrate to depolymerize the polymer, wherein a carbon bonded to a nitrogen atom contained in an isocyanate group of the isocyanate is a secondary or tertiary non-aromatic carbon.

A method is provided for sealing a seam in a self-aligned contact (SAC) layer that is disposed on a gate of a semiconductor structure. The method includes depositing a filler in the seam to seal the seam.

An object is to shorten the time for rewriting data in memory cells. A memory module includes a first memory cell, a second memory cell, a selection transistor, and a wiring WBL1. The first memory cell includes a first memory node. The second memory cell includes a second memory node. One end of the first memory cell is electrically connected to the wiring WBL1 through the selection transistor. The other end of the first memory cell is electrically connected to one end of the second memory cell. The other end of the second memory cell is electrically connected to the wiring WBL1. When the selection transistor is on, data in the first memory node is rewritten by a signal supplied through the selection transistor to the wiring WBL1. When the selection transistor is off, data in the first memory node is rewritten by a signal supplied through the second memory node to the wiring WBL1.

A field effect transistor includes a substrate, a passivation layer on the substrate forming a passivated substrate, wherein the passivation layer is inert to XeF.sub.2, and a graphene lateral heterostructure field effect transistor (LHFET) on the passivated substrate.

Methods are presented for forming multi-threshold field effect transistors. The methods generally include depositing and patterning an organic planarizing layer to protect underlying structures formed in a selected one of the nFET region and the pFET region of a semiconductor wafer. In the other one of the nFET region and the pFET region, structures are processed to form an undercut in the organic planarizing layer. The organic planarizing layer is subjected to a reflow process to fill the undercut. The methods are effective to protect a boundary between the nFET region and the pFET region.